U.S. patent application number 16/700006 was filed with the patent office on 2020-06-11 for sedentary period detection utilizing a wearable electronic device.
The applicant listed for this patent is Fitbit, Inc.. Invention is credited to Jacob Antony Arnold, Allison Maya Russell, Zachariah Lord Wasson, II, Shelten Gee Jao Yuen.
Application Number | 20200184793 16/700006 |
Document ID | / |
Family ID | 56367921 |
Filed Date | 2020-06-11 |
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United States Patent
Application |
20200184793 |
Kind Code |
A1 |
Arnold; Jacob Antony ; et
al. |
June 11, 2020 |
SEDENTARY PERIOD DETECTION UTILIZING A WEARABLE ELECTRONIC
DEVICE
Abstract
Systems and methods for determining a sedentary state of a user
are described. Sensor data is collected and analyzed to calculate
metabolic equivalent of task (MET) measures for a plurality of
moments of interest. Based on the MET measures and a time period
for which the MET measures exceed a threshold value, it is
determined whether the user is in a sedentary state. If the user is
in the sedentary state, the user is provided a notification to
encourage the user to perform a non-sedentary activity.
Inventors: |
Arnold; Jacob Antony;
(Fremont, CA) ; Russell; Allison Maya; (Berkeley,
CA) ; Wasson, II; Zachariah Lord; (Berkeley, CA)
; Yuen; Shelten Gee Jao; (Berkeley, CA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Fitbit, Inc. |
San Francisco |
CA |
US |
|
|
Family ID: |
56367921 |
Appl. No.: |
16/700006 |
Filed: |
December 2, 2019 |
Related U.S. Patent Documents
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Application
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Filing Date |
Patent Number |
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15671063 |
Aug 7, 2017 |
10497246 |
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16700006 |
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15078981 |
Mar 23, 2016 |
9728059 |
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15671063 |
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14221234 |
Mar 20, 2014 |
9801547 |
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15078981 |
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14156413 |
Jan 15, 2014 |
9241635 |
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14221234 |
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62137750 |
Mar 24, 2015 |
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61752826 |
Jan 15, 2013 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
A61B 5/1116 20130101;
A61B 5/681 20130101; A61B 5/7264 20130101; G06F 19/3481 20130101;
A61B 5/02055 20130101; A61B 5/746 20130101; A61B 5/1123 20130101;
A61B 5/222 20130101; G16H 20/40 20180101; G01C 22/006 20130101;
A61B 5/02416 20130101; A61B 2560/0209 20130101; A61B 5/0533
20130101; A61B 5/743 20130101; A61B 2560/0242 20130101; G16H 40/63
20180101; A61B 5/0022 20130101; G08B 21/0415 20130101; A61B 5/021
20130101; G16H 20/30 20180101; A61B 5/1118 20130101; A61B 5/7267
20130101; A61B 5/4809 20130101; A61B 2562/0219 20130101 |
International
Class: |
G08B 21/04 20060101
G08B021/04; G16H 40/63 20060101 G16H040/63; A61B 5/11 20060101
A61B005/11; A61B 5/00 20060101 A61B005/00; A61B 5/0205 20060101
A61B005/0205; G16H 20/40 20060101 G16H020/40 |
Claims
1. (canceled)
2. A system comprising: a wearable electronic device to be worn by
a user, the wearable electronic device including one or more
sensors configured to generate sensor data for a plurality of
moments of interest; one or more processors; and a non-transitory
machine-readable storage medium storing computer-executable
instructions which, when executed by the one or more processors,
cause the one or more processors to: obtain sensor data generated
by the one or more sensors of the wearable electronic device,
determine analyzed sensor information for each moment of interest
of a first set of moments of interest of the plurality of moments
of interest based on the sensor data for that corresponding moment
of interest, the first set corresponding to a first window of time,
determine, at a first point within the first window of time, that a
first goal for the first window of time has not been achieved based
at least on the analyzed sensor information for the moments of
interest of the first set, and cause a first notification to be
generated responsive to determining that the first goal has not
been achieved at the first point within the first window of
time.
3. The system of claim 2, wherein the first goal is based on input
received from a user.
4. The system of claim 2, wherein the first goal is a number of
steps taken during the first window of time.
5. The system of claim 2, wherein the non-transitory
machine-readable storage medium stores additional
computer-executable instructions to cause the one or more
processors to: classify each moment of interest of the first set
into a status of a plurality of statuses, wherein the statuses
include a sedentary status and a non-sedentary status, based at
least on the analyzed sensor information, and determine whether the
first goal for the first window of time has been achieved based on
the statuses for the moments of interest of the first set.
6. The system of claim 5, wherein the non-transitory
machine-readable storage medium stores additional
computer-executable instructions to cause the one or more
processors to determine whether the first goal for the first window
of time has been achieved based on whether a duration of
consecutive moments of interest of the first set that have been
classified as having the non-sedentary status exceeds a
threshold.
7. The system of claim 2, wherein the duration of the first window
of time is based on input received from a user.
8. The system of claim 2, wherein the duration of the first window
of time is between 10 minutes and 6 hours.
9. The system of claim 2, wherein the duration of the first window
of time is 60 minutes and the first point is 10 minutes before the
end of the first window of time.
10. The system of claim 2, wherein the first point is an amount of
time prior to the end of the first window of time.
11. The system of claim 10, wherein the amount of time is based on
input received from a user.
12. The system of claim 2, wherein the non-transitory
machine-readable storage medium stores additional
computer-executable instructions to cause the one or more
processors to: determine, at a second point in time after the first
point in time and within the first window of time, that the first
goal for the first window of time has been achieved based at least
on the analyzed sensor information for the moments of interest of
the first set; and cause a second notification to be generated
responsive to determining that the first goal has been
achieved.
13. The system of claim 2, wherein the non-transitory
machine-readable storage medium stores additional
computer-executable instructions to cause the one or more
processors to: determine analyzed sensor information for each
moment of interest of a second set of moments of interest of the
plurality of moments of interest based on the sensor data for that
corresponding moment of interest, the second set corresponding to a
second window of time, the second window of time immediately after
the first window of time, determine, at a second point within the
second window of time, that a second goal for the second window of
time has not been achieved based at least on the analyzed sensor
information for the moments of interest of the second set, and
cause a second notification to be generated responsive to
determining that the goal has not been achieved at the second point
within the second window of time.
14. The system of claim 13, wherein the duration of the first
window of time and the duration of the second window of time are
equal.
15. The system of claim 13, wherein the first point and the second
point are the same amount of time prior to the end of the
corresponding window of time.
16. The system of claim 13, wherein the first goal and the second
goal are equal.
17. The system of claim 2, wherein the non-transitory
machine-readable storage medium stores additional
computer-executable instructions to cause the one or more
processors to: classify each moment of interest in the plurality of
moments of interest into a status of a plurality of statuses, the
plurality of statuses including a sedentary status and a
non-sedentary status, based at least on the analyzed sensor
information; detect a first time period for which a number of
consecutive moments of interest have been classified as having the
sedentary status; classify the first time period as a sedentary
state based on the first time period being greater than a threshold
value; and cause a notification to be generated based on the first
time period being greater than the threshold value.
18. The system of claim 17, wherein the non-transitory
machine-readable storage medium stores additional
computer-executable instructions to cause the one or more
processors to: determine that a user associated with the wearable
electronic device is asleep or is not wearing the wearable
electronic device during a first moment of interest; and not
classify the first moment of interest as having the sedentary
status or the non-sedentary status.
19. The system of claim 2, wherein the analyzed sensor information
is a metabolic equivalent of task measure, motion measure, or heart
rate measure.
20. The system of claim 2, wherein the moments of interest occur at
regular time intervals.
21. The system of claim 2, wherein the analyzed sensor information
for each moment of interest is a single value.
22. The system of claim 2, wherein the one or more processors and
the non-transitory machine-readable storage medium are located in
the wearable electronic device.
23. The system of claim 2, wherein at least one of the one or more
processors and the non-transitory machine-readable storage medium
are located in a separate electronic device that is not the
wearable electronic device.
Description
INCORPORATION BY REFERENCE
[0001] An Application Data Sheet is filed concurrently with this
specification as part of the present application. Each application
that the present application claims benefit of or priority to as
identified in the concurrently filed Application Data Sheet is
incorporated by reference herein in its entirety and for all
purposes.
FIELD
[0002] Embodiments described in the present disclosure relate to
the field of wearable electronic devices. Specifically, the
embodiments relate to automatic detection of sedentary periods and
promotion of non-sedentary behavior utilizing a wearable electronic
device.
BACKGROUND
[0003] Trackers have gained popularity among consumers. A tracker
is used to track a user's activities using a variety of sensors and
helps the user to maintain a healthy life style. In order to
determine the activities, the tracker collects activity data and
runs computations on that data. One difficulty of obtaining
accurate determinations of the activities is that the trackers,
because they are worn by a user, are typically packaged in a
compact casing containing less powerful processor(s) on which it is
harder to run complex computations than larger electronic
devices.
[0004] Another challenge in tracking the activities is
differentiating between the user being stationary but performing an
activity and the user being sedentary, e.g., spending minimal
energy expenditure, etc. To illustrate, the user spends minimal
energy when the user is seated, or seated and typing at a computer.
Increased total sedentary time and longer sustained sedentary
periods are associated with poor health and fitness, e.g., obesity,
metabolic disorders, etc.
SUMMARY
[0005] In some embodiments, a wearable electronic device to be worn
by a user is described. The wearable electronic device includes a
set of one or more sensors to generate sensor data associated with
the user when the user is wearing the wearable electronic device.
The wearable electronic device further includes a set of one or
more processors coupled to the set of sensors and a non-transitory
machine readable storage medium coupled to the set of one or more
processors and having stored therein instructions. When the
instructions are executed by the set of one or more processors, the
instructions cause the wearable electronic device to track a period
of time during which a state of the user is determined to be
sedentary. The determination is based on metabolic equivalent of
task (MET) measures at moments of interest and the MET measures are
calculated based on the sensor data. The instructions further cause
the user to receive a notification responsive to the tracked period
of time to encourage the user to limit the length of sedentary
periods.
[0006] In various embodiments, the instructions further cause the
wearable electronic device to classify, for each of the moments of
interest, a status of the user as being sedentary or non-sedentary
based on a MET measure for that moment of interest.
[0007] In several embodiments, a period of time is tracked based on
a determination of contiguous ones of the moments of interest for
which the status of the user is classified as sedentary.
[0008] In some embodiments, the status of the user at a moment of
interest is classified as sedentary when a MET measure for that
moment of interest is below a threshold MET value.
[0009] In various embodiments, the status of the user at a moment
of interest is classified as sedentary when a MET measure for that
moment of interest is between a first threshold value and a second
threshold value, and the moment of interest is preceded by a first
moment of interest within a threshold window of time for which the
status of the user is sedentary, and is followed within the
threshold window of time by a second moment of interest for which
the status of the user is sedentary.
[0010] In some embodiments, one of the one of more sensors is a
photoplethysmographic (PPG) sensor, and the MET measures are based
on heart rate measures of the user calculated based on PPG sensor
data.
[0011] In various embodiments, the instructions cause the wearable
electronic device to filter out a period of time at which the state
of the user is asleep.
[0012] In some embodiments, the wearable electronic device includes
a sensor to generate sensor data associated with the user when the
user is wearing the wearable electronic device. The wearable
electronic device further includes a set of one or more processors
coupled to the sensor and a non-transitory machine readable storage
medium coupled to the set of one or more processors and having
stored instructions therein. The instructions when executed by the
set of one or more processors, cause the wearable electronic device
to track a period of time during which the state of the user is
determined to be sedentary based on the sensor data. The period of
time has a beginning and an end. The instructions further cause the
wearable electronic device to detect, responsive to the end of the
period of time, that the state of the user has changed from
sedentary to non-sedentary for a threshold period of time. The
instructions cause the wearable device to cause the user to receive
a notification responsive to the detection to encourage the user to
remain non-sedentary.
[0013] In several embodiments, a notification is a message
displayed on a display device of the wearable electronic device, or
a vibration of the wearable electronic device, or a sound emitted
by the wearable electronic device.
[0014] In some embodiments, a notification is indicative of the
user having ended the period of time during which the state of the
user is sedentary.
[0015] In various embodiments, a notification is determined based
on preferences set by the user.
[0016] In some embodiments, a notification is a motivational
statement displayed on the display device of the wearable
electronic device.
[0017] In various embodiments, an apparatus to improve an
effectiveness of notifications provided to the user of the wearable
electronic device is described. The apparatus includes an
electronic device including a sedentary state monitor to notify the
user of the wearable electronic device to encourage the user to
alter his/her sedentary behavior based on tracking periods of time
during which the user is sedentary. The sedentary state monitor
includes a set of one or more managers to receive a current state
from a plurality of states of the user during periods of time. The
states include a sedentary state. The one or more managers cause
the wearable electronic device to receive notifications based on
the current state to notify the user to limit a length of time
during which the user is in the sedentary state.
[0018] In some embodiments, the apparatus further includes a
sedentary learning unit coupled to receive data from each of the
one or more managers concerning the notifications. The sedentary
learning unit is coupled to a set of one of more sensors of the
wearable electronic device to determine which notifications has an
effect of modifying the sedentary behavior of the user, and to
determine an updated configuration of at least one of the one or
more managers. The updated configuration improves the user's
response to the notifications to limit a length of a period of time
during which the user is in the sedentary state.
[0019] In various embodiments, the one or more managers include a
sedentary alert manager that receives a period of time for the
current state of the user. The sedentary alert manager generates a
sedentary alert based on a detection that the period of time
exceeds a sedentary period of time threshold value. The sedentary
alert manager sends a notification to the wearable electronic
device indicating that the period of time exceeds the sedentary
period of time threshold value.
[0020] In some embodiments, the one or more managers further
include a non-sedentary state transition manager to receive the
current state of the user. The non-sedentary state transition
manager generates a notification that is based on a detection of an
end of a sedentary period of time for the current state. The
notification is sent from the non-sedentary state transition
manager to the wearable electronic device.
[0021] In various embodiments, the sedentary learning unit
determines based on notification information received from the
sedentary alert manager and the non-sedentary state transition
manager an updated configuration of at least one of the sedentary
alert manager and the non-sedentary state transition manager. The
updated configuration improves the user's response to the
notification information to limit a length of a sedentary period of
time during which the user is in the sedentary state.
[0022] In some embodiments, the updated configuration includes
disabling at least one of the sedentary alert manager and the
non-sedentary state transition manager.
[0023] In several embodiments, the sedentary learning unit includes
a decision tree, a random forest, a support vector machine, neural
network, a K-nearest neighbor, a Naive Bayes, or Hidden Markov
models.
[0024] In various embodiments, the sedentary learning unit allows
the user to snooze a notification.
[0025] In some embodiments, the sedentary learning unit uses data
related to the snoozed notification to determine an updated
configuration of at least one of the one or more managers.
[0026] In various embodiments, the electronic device is a wearable
electronic device.
BRIEF DESCRIPTION OF THE DRAWINGS
[0027] Embodiments described in the present disclosure are
illustrated by way of example, and not by way of limitation, in the
figures of the accompanying drawings in which like references
indicate similar elements.
[0028] FIG. 1A illustrates sedentary user state detection and
sedentary alert management, according to various embodiments
described in the present disclosure.
[0029] FIG. 1B illustrates a flow diagram of operations for
tracking sedentary periods of time and causing a user to receive
notifications based on the sedentary periods, according to some
embodiments described in the present disclosure.
[0030] FIG. 2 illustrates a use of sedentary and non-sedentary
statuses of the user to determine periods of time in which a state
of the user is sedentary, according to several embodiments
described in the present disclosure.
[0031] FIG. 3 illustrates a sedentary state monitor for notifying
the user based on tracking of the sedentary periods of time to
encourage the user to alter his/her sedentary behavior and to limit
a length of the sedentary periods, according to some embodiments
described in the present disclosure.
[0032] FIG. 4 illustrates a communication of a notification to the
user based on a detection of an end of a sedentary period of time
and of a beginning of a non-sedentary period of time, which has
exceeded a threshold period of time, according to various
embodiments described in the present disclosure.
[0033] FIG. 5 illustrates a communication of a sedentary alert to
the user based on a detection of the sedentary period of time
exceeding a sedentary period of time threshold value, according to
some embodiments described in the present disclosure.
[0034] FIG. 6A illustrates a recordation of metabolic equivalent of
task (MET) measures at consecutive moments of interest over a
period of time and a classification of a status of the user at each
moment of interest based on the MET measures, in accordance with
various embodiments described in the present disclosure.
[0035] FIG. 6B illustrates a recordation of the MET measures at
consecutive moments of interest over a period of time and the
classification of the status of the user at each moment of interest
based on the MET measures, in accordance with some embodiments
described in the present disclosure.
[0036] FIG. 7 is a block diagram illustrating a wearable electronic
device and an electronic device implementing operations disclosed
herein, according to various embodiments described in the present
disclosure.
[0037] FIG. 8 is a block diagram of a wrist-mounted electronic
device having a button, a display, and a wrist band to secure the
wrist-mounted electronic device to a forearm of the user, according
to some embodiments described in the present disclosure.
DETAILED DESCRIPTION
[0038] In the following description, numerous specific details are
set forth. However, it is understood that embodiments described in
the present disclosure may be practiced without these specific
details. In other instances, well-known circuits, structures and
techniques have not been shown in detail in order not to obscure an
understanding of the embodiments. It will be appreciated, however,
by one skilled in the art that the embodiments may be practiced
without such specific details. Those of ordinary skill in the art,
with a description of the embodiments, will be able to implement
appropriate functionality of the embodiments without undue
experimentation.
[0039] In some embodiments, the terms "coupled" and "connected,"
along with their derivatives, are used. It should be understood
that these terms are not intended as synonyms for each other. For
example, "coupled" is used to indicate that two or more elements,
which are or are not in direct physical or electrical contact with
each other, co-operate or interact with each other. Moreover, in
this example, "connected" is used to indicate an establishment of
communication between two or more elements that are coupled with
each other. Furthermore, in various embodiments, a "set", as used
herein, refers to any positive whole number of items, including one
item, unless stated otherwise, such as, a set of zero or more.
[0040] In some embodiments, an electronic device stores a code
internally and/or transmits the code to other electronic devices
over a computer network. The code is composed of software
instructions and is sometimes referred to as computer program code
or a computer program stored within a machine-readable storage
media. In some embodiments, the code includes data for execution of
the code. In various embodiments, the machine-readable storage
media is computer-readable media. Examples of the computer-readable
media include magnetic disks, optical disks, read only memory
(ROM), random access memory (RAM), flash memory devices, phase
change memory, etc. In various embodiments, the code is sent using
a machine-readable transmission media, also called a carrier, such
as, for example, electrical, optical, radio, acoustical, or other
form of propagated signals. Further examples of the carrier include
carrier waves, infrared signals, etc.
[0041] In various embodiments, the electronic device, e.g., a
computer, etc., includes hardware and software. For example, the
electronic device includes one or more processors coupled to one or
more machine-readable storage media to store the code for execution
on the one or more processors and/or to store data. To further
illustrate, the electronic device includes a non-volatile memory
containing the code and the non-volatile memory stores the code or
data even when the electronic device is turned off, e.g., when
power to the electronic device is removed, etc. While the
electronic device is turned on, a part of the code that is to be
executed by the one or more processors of the electronic device is
copied from the non-volatile memory into a volatile memory, e.g., a
dynamic random access memory (DRAM), a static random access memory
(SRAM), etc., of the electronic device. The non-volatile memory is
slower to access than the volatile memory. The electronic device
typically also includes a set of one or more network interface(s),
e.g., a network interface controller, a network interface card, an
Internet access card, an Internet access controller, etc., each of
which establishes physical or wireless network connections with the
other electronic devices to communicate the code and/or data using
the propagated signals. A wearable electronic device (WED), further
described in detail below, is an example of the electronic device.
It should be noted that one or more parts of an embodiment
described in the present disclosure may be implemented using
different combinations of software, firmware, and/or hardware.
[0042] Embodiments describing tracking of a sedentary state of a
user and generation of a sedentary notification follow.
[0043] FIG. 1A illustrates sedentary state detection and sedentary
alert management, according to some embodiments described in the
present disclosure. It should be noted that task boxes 1, 2, 3A,
3B, and 4 of FIG. 1A are executed and components 110, 112, 120,
122, 124, and 126 of FIG. 1A are implemented, in some embodiments,
in the wearable electronic device, or distributed between the
wearable electronic device and one or more of the other electronic
devices coupled to the wearable electronic device. In some
embodiments, the wearable electronic device is worn on a body part,
e.g., an arm, a wrist, an ankle, or a chest, etc., of the user, or
embedded in a garment worn by the user. Examples of the one or more
other electronic devices include a server including hardware and
software, a tablet, a smartphone, a desktop computer, a laptop
computer, and a smart television. In some embodiments, the one or
more other electronic devices execute an application, sometimes
referred to as an app, to implement, for example, a sensor data
analyzer 112, a user state tracking unit 190, and/or a sedentary
notification unit 192.
[0044] The task boxes 1-4 illustrate an order in which operations
are performed by the components 110, 112, 120, 122, 124, and 126.
As illustrated by the task box 1, one or more sensors 110 generate
sensor data 150 for a plurality of time intervals. For example, the
one or more sensors 110 are implemented in the wearable electronic
device, such that, when worn by the user, at least some of the
sensor data is indicative of an activity performed by the user. An
example of the sensor data includes biometric data. In some
embodiments, the one or more sensors 110 that generate the sensor
data 150 include a motion sensor, e.g., a three axis accelerometer,
etc. The motion sensor generates motion sensor data indicative of a
motion, e.g., a number of steps taken by, a number of floors
climbed by, a number of floors descended by, etc., of the user. In
various embodiments, the one or more sensors 110 include a heart
rate sensor, e.g., a photoplethysmographic (PPG) sensor, etc., to
generate heart sensor data, e.g., PPG sensor data, etc., indicative
of a heart rate of the user. In several embodiments, both the
motion sensor and the heart rate sensor are housed in the same
wearable electronic device or in different wearable electronic
devices. In some embodiments, other types of sensors, e.g., a
gyroscope, a gravity sensor, a rotation vector sensor, a
magnetometer, a temperature sensor to measure a temperature of the
user's skin and/or an environment surrounding the user, an ambient
light sensor to measure an ambient light of the environment, a
galvanic skin response sensor, a capacitive sensor, a humidity
sensor, a sound sensor, etc., are housed in the wearable electronic
device or in multiple wearable electronic devices. Examples of the
environment surrounding the user include a room in which the user
is situated, a street on which the user is standing or driving, an
interior of a vehicle in which the user is situated, etc. In
several embodiments, some or all of the sensor data 150 is
generated by one of the one or more other electronic devices
described above and received by the wearable electronic device from
the one of the one or more other electronic devices.
[0045] The sensor data 150 generated during a time interval is
processed by the sensor data analyzer 112. In some embodiments, a
subset of the sensor data 150 is generated by performing a
statistical operation, e.g., averaging, etc., on the sensor data
150 and is processed by the sensor data analyzer 112. At the task
box 2, the sensor data analyzer 112 analyzes the sensor data 150
received from the one or more sensors 110 and calculates analyzed
sensor information 152 for each moment of interest, and the
analyzed sensor information 152 is used to determine a status,
e.g., sedentary status or non-sedentary status, etc., of the user.
In some embodiments, the analyzed sensor information 152 is
calculated for a plurality of moments of interest at regular
intervals of time, e.g., an interval within a range of 30
seconds-1.5 minute, a 1 minute interval, an interval within a range
of 0.5 second-1.5 seconds, a 1 second interval, etc. In various
embodiments, the intervals of time are configurable and dynamically
adjusted, e.g., reduced or increased based on various factors,
etc., and/or capable of being automatically disabled and/or
manually disabled by the user for spans of time to save power.
[0046] In some embodiments, the analyzed sensor information 152 is
metabolic equivalent of task (MET) measures, where each MET is
determined for a moment of interest. A MET measure is a normalized
measure of energy expenditure, which increases with activity and is
non-zero at a moment of interest. For example, a MET measure for an
inactive or asleep status or not wearing status is close to 1.0, a
MET measure for the user while walking is generally above 2.0, and
a MET measure for the user while swimming is between 10.0 and 11.0.
While in some embodiments the analyzed sensor information 152 is
MET measures, various embodiments use different measures, e.g.,
motion measures indicative of a motion of the user wearing the
wearable electronic device, heart rate measures indicative of the
heart rate of the user, etc. The motion measures are sometimes
referred to herein as movement measures. Examples of the motion
measures include a number of steps taken by the user, a number of
floors climbed or descended by the user, etc. In various
embodiments, the heart rate sensor, e.g., a heart rate monitor,
etc., generates the heart sensor data indicative of a heart rate of
the user and calculates the heart rate measures of the user.
[0047] The analyzed sensor information 152 for moments of interest
is used by the user state tracking unit 190 to generate a state 156
of the user for different periods of time. In some embodiments,
each period of time typically includes multiple contiguous moments
of interest. In various embodiments, each period of time is as
small as one moment of interest. The user state tracking unit 190
includes a user status identifier 120 that classifies each moment
154 of interest into the status of the user based on the analyzed
sensor information 152 for that moment of interest. The statuses of
the user are classified into the sedentary status and the
non-sedentary status, as indicated in the task box 3A.
[0048] In some embodiments, the user status classifier 120
classifies the status of the user for the moment 154 of interest as
being sedentary, e.g., seated, seated and typing at a computer,
typing at a computer, etc., or non-sedentary, e.g., active,
running, walking, exercising, dancing, swimming, etc. It should be
noted that in various embodiments, when the status of the user is
classified as non-sedentary, the user is spending a higher amount
of energy compared to energy expended by the user when the status
of the user is classified as sedentary. Several methods for
classifying the moment 154 of interest are described in more detail
below with reference to FIGS. 6A-6B.
[0049] In various embodiments, a MET measure is used to determine
the non-sedentary status of the user and associates the
non-sedentary status with a particular type of activity of the
user. For example, according to a MET measure, the user status
classifier 120 determines whether the user is running, walking,
sprinting, bicycling, swimming, or performing another type of
non-sedentary activity.
[0050] As described in the task box 3B, a time period detector 122
of the user state tracking unit 190 detects periods of time during
which a state of the user is sedentary based on contiguous moments
of interest for which the status of the user is classified as
sedentary. For example, according to some embodiments described
below with reference to FIG. 2, a block of time is determined by
the time period detector 122 to have a sedentary state when it is
determined by the time period detector 122 that the block of time
includes contiguous moments of interest of sedentary statuses.
[0051] The state 156 of the user for different periods of time is
used by the sedentary notification unit 192 to generate one or more
sedentary alerts 158 to notify the user. Examples of the one or
more sedentary alerts 158 are provided below. The one or more
sedentary alerts 158 encourage the user to limit a length of
sedentary time periods. At the task box 4, a sedentary state
monitor 124 of the sedentary notification unit 192 generates the
one or more sedentary alerts 158, e.g., a notification, etc., for
providing to the user to encourage the user to alter his/her
sedentary behavior. The one or more sedentary alerts 158 are
provided to the user through a user interface 126, which includes a
display device of the wearable electronic device. In some
embodiments, the user receives the one or more sedentary alerts 158
through a vibration of the wearable electronic device, a message
displayed on the display device of the wearable electronic device,
and/or a sound emitted by a speaker within the wearable electronic
device.
[0052] In some embodiments, the sensor data analyzer 112 is located
within the wearable electronic device or within one of the other
electronic devices. For example, a processor of the wearable
electronic device or of one of the other electronic devices
performs operations described herein as being performed by the
sensor data analyzer 112. In several embodiments, the user status
classifier 120 is located within the wearable electronic device or
in one of the other electronic devices. For example, the processor
of the wearable electronic device or of one of the other electronic
devices performs operations described herein as being performed by
the user status classifier 120. In various embodiments, the time
period detector 122 is located within the wearable electronic
device or in one of the other electronic devices. For example, the
processor of the wearable electronic device or of one of the other
electronic devices performs operations described herein as being
performed by the time period detector 122. In several embodiments,
the sedentary state monitor 124 is located within the wearable
electronic device or in one of the other electronic devices. For
example, the processor of the wearable electronic device or of one
of the other electronic devices performs operations described
herein as being performed by the sedentary state monitor 124. In
some embodiments, the user interface 126 is located within the
wearable electronic device or in one of the other electronic
devices. For example, the processor of the wearable electronic
device or of one of the other electronic devices performs
operations described herein as being performed by the user
interface 126. Examples of a processor include an application
specific integrated circuit (ASIC), a programmable logic device
(PLD), a central processing unit, a microprocessor, a controller, a
microcontroller, etc.
[0053] In some embodiments, instead of the processor of the
wearable electronic device performing the operations described
herein as being performed by the sensor data analyzer 112, the user
status classifier 120, the time period detector 122, the sedentary
state monitor 124, and the user interface 126, different processors
of the wearable electronic device perform the operations. For
example, a processor of the wearable electronic device performs an
operation described herein as being performed by the sensor data
analyzer 112, another processor of the wearable electronic device
performs an operation described herein as being performed by the
user status classifier 120, yet another processor of the wearable
electronic device performs an operation described herein as being
performed by the time period detector 122, another processor of the
wearable electronic device performs an operation described herein
as being performed by the sedentary state monitor 124, and another
processor of the wearable electronic device performs an operation
described herein as being performed by the user interface 126.
Similarly, in various embodiments, instead of the processor of one
of the other electronic devices performing the operations described
herein as being performed by the sensor data analyzer 112, the user
status classifier 120, the time period detector 122, the sedentary
state monitor 124, and the user interface 126, different processors
of the one of the other electronic devices perform the
operations.
[0054] In various embodiments, one or more processors of the
wearable electronic device perform the operations described herein
as being performed by the sensor data analyzer 112, the user status
classifier 120, the time period detector 122, the sedentary state
monitor 124, and the user interface 126. Similarly, in some
embodiments, one or more processors of one of the other electronic
devices perform the operations described herein as being performed
by the sensor data analyzer 112, the user status classifier 120,
the time period detector 122, the sedentary state monitor 124, and
the user interface 126.
[0055] It should be noted that in embodiments in which tasks
described above with reference to task boxes 2 through 4 are
performed by the components 112, 120, 122, and 124 located in one
of the other electronic devices, the wearable electronic device
includes a display device to display the one or more sedentary
alerts 158. Moreover, in these embodiments, the wearable electronic
device and one of the other electronic devices communicate with
each other via a communication medium, e.g., a universal serial bus
cable, a wireless protocol air medium, a serial cable, a parallel
cable, etc. An example of the wireless protocol includes
Bluetooth.TM..
[0056] FIG. 1B illustrates a flow diagram of a method for tracking
a sedentary period of time and causing the user to receive
notifications based on the sedentary period of time, according to
various embodiments described in the present disclosure. At an
operation 102 of the method, a period of time during which the
state of the user is determined to be sedentary, sometimes referred
to herein as the "sedentary period of time", is tracked by the time
period detector 122. The determination of the period of time is
based on the MET measures for individual non overlapping moments of
interest within each period of time. Further, in some embodiments,
the MET measures are generated within the wearable electronic
device based on the sensor data 150 received from the one or more
sensors 110 (FIG. 1A), e.g., a three axis accelerometer and a heart
rate sensor, etc. Examples of the MET measures include movement
measures calculated based on the sensor data 150 from the motion
sensor and heart rate measures calculated based on the sensor data
150 from the heart rate sensor housed within the same wearable
electronic device. If a length of the sedentary period of time
exceeds a pre-determined threshold time period, it is determined by
the time period detector 122 that the state of the user is
sedentary.
[0057] At an operation 104 of the method for tracking the sedentary
period of time, an act of providing the user with notifications to
encourage the user to limit a length of the sedentary period of
time is performed based on the tracking at the operation 102. In
some embodiments, the operation 104 is performed within the
wearable electronic device and the user is notified by receiving a
message on the display device of the wearable electronic device, a
vibration of the wearable electronic device, and/or a sound emitted
by speakers of the wearable electronic device.
[0058] In some embodiments, a notification, as described herein, is
an electronic notification that is sent to a display device. For
example, the electronic notification is rendered by a processor to
be displayed on a display device. In various embodiments, the
electronic notification is provided in the form of a vibration or a
sound.
[0059] FIG. 2 illustrates a use of the user's statuses of sedentary
or non-sedentary to determine period of times in which the state of
the user is sedentary according to some embodiments described in
the present disclosure. As illustrated in FIG. 2, the statuses are
illustrated as either sedentary or non-sedentary over time, e.g.,
at each moment of interest, etc. From the sedentary or
non-sedentary statuses, non-overlapping, consecutive periods of
time are derived. During each of the consecutive periods of time,
the user is in either a sedentary state or a non-sedentary state.
Each of the consecutive periods of time span one or more moments of
interest. Also, as illustrated in FIG. 2, the consecutive periods
of time have different states of the user, and the consecutive
periods of time are described by the task box 3B.
[0060] Specifically, FIG. 2 shows that the consecutive periods of
time are derived: a sedentary period 252, a non-sedentary period
254, and a sedentary period 256, each of which spans multiple
contiguous moments of interest for which the status of the user is
identical. The sedentary period 252 includes 6 moments of interest
each of which has the status classified as sedentary.
Comparatively, the non-sedentary period 254 includes 5 moments of
interest, each of which has the status classified as non-sedentary.
Transitions between the states of the user are represented by edges
of the periods of time. e.g., when one time period ends and the
next begins, etc., To illustrate, the state of the user transitions
from the sedentary state to the non-sedentary state at an end of
the sedentary period 252 of time and at a beginning of the
non-sedentary period 254 of time.
[0061] In some embodiments, the time period detector 122 (FIG. 1A)
detects and records alternating periods of time in which the state
of the user is sedentary or non-sedentary. For example, the
sedentary periods of time 252 and 256, and the non-sedentary period
of time 254, illustrated in FIG. 2, are recorded over a span of
time, e.g., an hour, a day, a week, etc., to be presented to the
user or to perform further analysis with regard to a sedentary
behavior of the user. The determined periods of time with the
states, e.g., the sedentary state, the non-sedentary state, etc.,
are presented to the user on the display device of the wearable
electronic device or a display device of one of the other
electronic devices, e.g., a tablet, a smartphone, a computer, etc.,
which receives the determined periods of time and the states as
data from the wearable electronic device. In some embodiments, the
one of the other electronic devices generates the determined
periods of time and the states. The user then views his/her
sedentary behavior indicated by the determined periods of time and
the states, and tracks his/her improvement over time.
[0062] In some embodiments, the user shares information about
his/her sedentary behavior with friends, colleagues, or teammates
via a network, e.g., a social network, etc. The friends,
colleagues, or teammates compete with each other based on their
respective sedentary states determined by their respective recorded
sedentary periods.
[0063] In various embodiments, additional sensor data is used to
further disambiguate between sedentary periods and other time
periods during which the user is asleep and/or not wearing the
wearable electronic device. The wearable electronic device is able
to detect time periods during which the user is asleep or not
wearing the wearable electronic device. For example, the one or
more sensors 110 cannot detect information, e.g., the motion sensor
data, the heart sensor data, number of steps taken, etc., about the
user. To further illustrate, when the wearable electronic device is
not being worn by the user, the one or more sensors detect a number
of steps taken by the user to be zero for a time period. The time
period satisfies the MET measures or motion based criteria for
sedentary time, but do not qualify as sedentary because the user is
not wearing the wearable electronic device or is asleep as is
detected by the one or more sensors 110. MET measures for the time
period during which the user is not wearing the wearable electronic
device, e.g., while sleeping, while showering, etc., or is asleep
are filtered out by the processor of the wearable electronic device
or the processor of one of the other electronic devices before or
during a time at which a determination of the sedentary and
non-sedentary statuses is made.
[0064] Embodiments describing the sedentary state monitor
follow.
[0065] Through an automatic detection and tracking of periods of
time in which the state of the user is sedentary, the user receives
notifications to encourage him/her to alter his/her behavior and be
less sedentary. The notifications promote breaking up long periods
of sedentary states and decrease an overall time that the user is
sedentary. FIG. 3 is a block diagram of an embodiment of the
sedentary state monitor 124 for notifying the user based on
tracking of sedentary periods of time to encourage the user to
alter his/her sedentary behavior and limit a length of the
sedentary periods, according to several embodiments described in
the present disclosure. The sedentary state monitor 124 includes a
management unit 310 that receives the states of the user for
periods of time. For example, the state is provided at an end of a
period of time after which a preceding state of the user has
changed. To illustrate, after a transition between two consecutive
states of the user, it is indicated to the management unit 310 that
a current period and the user's state has begun. As another
example, the states are provided as a current stream of information
that includes a transition between two consecutive states. As yet
another example, the states are provided in bulk at regular
intervals. To illustrate, a current period of time is thus far X
time long, and the management unit 310 detects transitions between
two consecutive states during X.
[0066] While FIG. 3 shows a non-sedentary state transition manager
320 of the management unit 310, a sedentary alert manager 330 of
the management unit 310, and a non-sedentary goal manager 340 of
the management unit 310, in some embodiments, the management unit
310 has more, less, and/or different types of managers. In
embodiments with multiple types of managers, one or some
combination of these managers are used at different times to
interact with the user, e.g., by sending notifications to the user
through the wearable electronic device of the user or through the
one of the other electronic devices based on sedentary states of
the user to encourage the user to alter or end a sedentary behavior
as discussed in more detail below.
[0067] Embodiments describing a behavior triggered alert, e.g., a
non-sedentary state transition, etc., follow.
[0068] In accordance with several embodiments, the user is
notified, e.g., via display of a notification, etc., on the
wearable electronic device upon detection that the sedentary period
of time has ended and the non-sedentary period of time has begun,
e.g., the user started moving, etc., and upon determination that
the non-sedentary period of time exceeded a threshold period of
time. While in some embodiments, the threshold period of time is
the same for all types of activities, in various embodiments, the
threshold period of time is different for at least certain type of
activities. The user receives the notification, e.g., a message
displayed on the display device of the wearable electronic device,
a vibration of the wearable electronic device, and/or a
congratulations sound on the wearable electronic device, etc., that
notifies the user that he/she has just ended a sedentary period of
time. The notification is intended to encourage the user to keep
moving and remain active to limit a total amount of time for which
the state of the user is sedentary.
[0069] FIG. 4 illustrates a communication of a notification to the
user based on a detection of an end of a sedentary period 424 of
time and a beginning of a non-sedentary period 426 of time, which
has exceeded the threshold period of time, according to some
embodiments described in the present disclosure. In some
embodiments, the time period detector 122 (FIG. 1A) detects the
sedentary period 424 of time of the user and upon detection 412
that the state of the user has changed from sedentary to
non-sedentary for the threshold period of time, the time period
detector 122 notifies the non-sedentary state transition manager
320 (FIG. 3), which communicates 414 a notification, e.g.,
non-sedentary state transition notification information, etc., to
the wearable electronic device of the user. As an example, it is
detected that the state of the user has changed from sedentary to
non-sedentary when a set of one or more moments of interest
included in the non-sedentary period 426 of time meet the threshold
period of time. In some embodiments, the state of the user is
detected to be non-sedentary when the user performs one of a
variety of activities, e.g., running, sprinting, walking briskly,
puttering around, etc., for a period of time, e.g., 30 seconds, 10
seconds, 1 minute, 3 minutes, etc.
[0070] In various embodiments, the non-sedentary period 426 of time
is determined by the time period detector 122 based on statuses of
the user at moments of interest. In some embodiments, an end of the
sedentary period 424 of time is detected when a non-sedentary state
of the user is detected.
[0071] In several embodiments, the non-sedentary state is detected
based on a type of activity that the user is performing. For
example, when the user runs for 30 seconds, e.g., the status of the
user is classified as "non-sedentary, running" for 30 seconds,
etc., a change in the state of the user from sedentary to
non-sedentary is detected and the user receives a notification. As
another example, when the user sprints for at least 10 seconds,
e.g., the status of the user is classified as "non-sedentary,
sprinting" for at least 10 seconds, etc., a change in the state of
the user from sedentary to non-sedentary is detected and the user
receives a notification. As yet another example, when the user
walks briskly for 1 minute, e.g., the status of the user is
classified as "non-sedentary, walking" for 1 minute, etc., a change
in the state of the user from sedentary to non-sedentary is
detected and the user receives a notification. As still another
example, when the user putters around for at least 3 minutes, e.g.,
the status of the user is classified as "non-sedentary, puttering"
for at least 3 minutes, etc., a change in the state of the user
from sedentary to non-sedentary is detected and the user receives a
notification.
[0072] In some embodiments, the time period detector 122 detects
the sedentary period 424 of time and upon detection 412, of a
non-sedentary moment of interest, e.g., one or more moments of
interest included in the non-sedentary period 426 of time, etc.,
the time period detector 122 notifies the non-sedentary state
transition manager 320, which determines that the non-sedentary
period of time exceeds the threshold period of time and
communicates 414 a notification to the wearable electronic device
of the user that the threshold period of time is met. The
notification that the threshold period of time is met is indicative
that the user has ended the sedentary period 424 of time and is now
active. The notification is intended to encourage the user to be
more active and break sedentary periods more often.
[0073] In various embodiments, the notification that the threshold
period of time is met is in the form of a sentence, or a
motivational statement, or a positive message displayed on the
display device of the wearable device. Examples of a non-exhaustive
list of exemplary motivational statements that indicate whether the
threshold period of time is met include "good job!," "great work,"
"keep moving," "keep going"; "don't stop"; "step more"; "xx hours
stationary" (where xx is how long the user has been sedentary);
"keep walking"; "take a xx minute walk" (where xx is a value
between 1-20, for example 2); "you got up after xx hours yy minutes
of sitting" (where xx is the number of hours and yy the number of
minutes the user is sedentary); "you're at x steps. can you get to
x+200?" (where x is the number of steps taken since ending the
sedentary period); "take the long way?"; "walking meeting?"; "let's
go!"; "Walk to success!"; "Let's call u butter cuz u on a roll!";
"you're on fire!"; "movin' and a groovin'"; "Don't stop movin' !
!"; "grab a friend, keep walking!"; "you can't catch me!"; "Good
job, you sat around for x hours and now you finally got up"; "up
and at 'em"; "walk like you just robbed a bank"; "Staying on top of
it!"; "way to go"; "Way to move!"; "Way to work it!"; "you did
it!"; "Looking healthy!"; "Good for you:)"; "Great!"; "score!"; and
"nice!", etc.
[0074] Embodiments describing rolling alerts follow.
[0075] In various embodiments, the user is notified through the
wearable electronic device upon detection that the user has been
sedentary for a threshold amount of time, which is sometimes
referred to herein as a threshold sedentary time period. When the
user has been sedentary for an extended period of time, a sedentary
alert is communicated to the user to inform him/her of the extended
period of time and encourage him/her to end the extended period.
The sedentary alert is a message displayed on the display device of
the wearable electronic device, a sound emitted by the wearable
electronic device, and/or a vibration of the wearable electronic
device. The sedentary alert is intended to encourage the user to
start moving and become active to end the sedentary period.
[0076] In some embodiments, the threshold sedentary time period is
1 hour, or 2 hours, or 20 minutes, or 40 minutes, or a few seconds,
or a few minutes, or a few hours. In various embodiments, the
threshold sedentary time period is configurable, e.g., the user
selects a length of a window of sedentary time after which he/she
would like to be notified to end the sedentary time. In several
embodiments, the threshold sedentary time period is dynamically
adjusted, e.g., reduced or increased based on various factors,
etc., and/or capable of being automatically disabled and/or
manually disabled by the user.
[0077] In some embodiments, the user sets preferences for a type of
alert to be received. For example the user selects a sound, a
particular message to be displayed, and/or a vibration. In various
embodiments, the user sets the sedentary state monitor 124 (FIG.
1A) such that sedentary periods of time are monitored within
specific intervals of times. For example, the sedentary periods or
non-sedentary periods of time are monitored during the day between
8 AM and 8 PM of a day and not monitored for remaining times of the
day.
[0078] In some embodiments, an input, e.g., one or more
preferences, etc., is received from the user via an input device,
e.g., a keypad, a touchscreen of the display device, a stylus,
etc., of the wearable electronic device or via an input device,
e.g., a keypad, a touchscreen of a display device, a stylus, a
keyboard, a mouse, etc., of one of the other electronic devices. In
embodiments in which the input is received at the wearable
electronic device and the sedentary state monitor 124 is located
within one of the other electronic devices, the input is
communicated from a communication device of the wearable electronic
device to a communication device of the one of the other electronic
devices. The communication device of the one of the other
electronic devices provides the input to the sedentary state
monitor 124 of the one of the other electronic devices. Examples of
a communication device includes a device that applies a Bluetooth
protocol, an Internet Protocol (IP), an Ethernet protocol, a
Transmission Control Protocol over IP (TCP/IP) protocol, a
Universal Serial Bus protocol, a serial transfer protocol, a
parallel transfer protocol, etc. In embodiments in which the input
is received at one of the other electronic devices and the
sedentary state monitor 124 is located within the wearable
electronic device, the input is communicated from the communication
device of the one of the other electronic devices to the
communication device of the wearable electronic device. The
communication device of the wearable electronic device provides the
input to the sedentary state monitor 124 of the wearable electronic
device.
[0079] FIG. 5 illustrates communication of a sedentary alert to the
user based on a detection of a sedentary period of time exceeding
the threshold sedentary time period, according to various
embodiments described in the present disclosure. The time period
detector 122 (FIG. 1A) detects 516 a sedentary period 528 of time
of the user and upon detection 516 that the sedentary period 528 of
time exceeds the threshold sedentary time period .DELTA.T, the
sedentary alert manager 330 communicates 518 a sedentary alert,
e.g., sedentary alert notification information, etc., to the
wearable electronic device of the user. The sedentary alert is
indicative that the user has spent more than .DELTA.T period of
time being in the sedentary state and he/she is encouraged to end
the sedentary period 528 of time by doing a more active task, e.g.,
walking, or running, or performing a physical activity with higher
energy expenditure than being sedentary, etc. The sedentary alert
is intended to inform the user of his/her sedentary behavior and
encourage him/her to be more active. In some embodiments, the
sedentary alert is in the form of a vibration of the wearable
electronic device or a sound emitted by the wearable electronic
device through the speaker of the wearable electronic device, a
sentence or a message displayed on the display device of the
wearable electronic device.
[0080] A non-exhaustive list of sedentary alerts includes: "time to
get moving!"; "How about a walk?"; "Get moving"; "care for a
stroll"; "Move those muscles!"; "Let's move"; "please get up"; "how
about a walk?"; "step it up!"; "take a break"; "stretch your legs";
"you were still for xx minutes" (where xx is how long the user has
been sedentary); "where you are today is where your mind put you!";
"take care of your body"; "get up!"; "don't just sit there"; "be
the example"; "get up, stand up"; "get up, get fit!"; "you've been
sitting for 1 hour"; "you know what time it is!"; "woof! let's
walk!"; "feed me steps"; "it's never to late to move!"; "time to
get steppin'"; "let's move"; "Move! Move! Move!"; "I'm bored. Let's
shake it!"; "go get 'em!"; "You can do anything you set your mind
to"; "Gonna fly now!"; "I dare you to move!"; "More steps please";
"Move your butt"; "UP UP UP"; "Stretccch"; "Waaalk"; "GETUPANDGO";
"Take a walk"; "Grab a friend, take a walk"; "When the going gets
sedentary, the sedentary get going!"; "I believe you can fly!";
"What have you done today to make me feel proud?"; "I want to run";
"Seize the day!"; "Run away!"; "I'm after you!"; "The British are
coming"; "Tick tick tick, you're blood sugar is rising"; "Shutup
and step"; "Hungry for steps"; "Error: Steps too low"; "Step
error"; "Have you forgotten what walking feels like?"; "If you were
my Fitbit, I'd walk you"; "it's been a while"; "Time to get up!";
"Get moving"; "Stop being an Eeyore"; "Hop to it"; "Make like a
bunny and hop to it"; "It's that time again!"; "Let's go get some
water"; "Let's go for a jaunt"; "care for a stroll?"; "stretch them
legs!" "streeeeeeaaaaatttccchhh"; "step up 2 the streets"; "now
walk it out"; "walk it out"; "left right LEFT!"; and "lets go find
some stairs!", etc. In some embodiments, the user alternatively or
additionally receives one or more icons, and/or one or more
animated images, e.g., animated feet, animated steps, etc.,
displayed on the display device of the wearable electronic device
and the one or more icons and/or the one or more animated images
indicate that the user is sedentary for greater than the threshold
sedentary time period .DELTA.T.
[0081] In various embodiments, upon receipt of the sedentary alert,
the user ends the sedentary time period. In several embodiments,
upon receipt of the sedentary alert, the user remains sedentary and
continues to receive sedentary alerts from the sedentary state
monitor 124 at regular time intervals encouraging him/her to move.
For example, the user receives sedentary alerts every hour.
[0082] In some embodiments, if the user ends the sedentary period
528 of time, the user receives, via the wearable electronic device,
a congratulations message from the sedentary state monitor 124,
also sometimes referred herein below as a celebration message, to
encourage him/her in his/her effort of ending the sedentary period
528 of time as described above. The celebration message is one of
celebration messages described further below.
[0083] Embodiments describing mini-goal alerts follow.
[0084] In some embodiments, the user is encouraged to achieve a
mini goal, e.g., 250 steps, or 15 minutes of consecutive
non-sedentary moments of interest, etc., during a predetermined
window of time. The mini goal is a step towards achieving a
predefined goal. The sedentary periods and the non-sedentary
activity of the user are tracked by the non-sedentary goal manager
340 (FIG. 3), which interacts with the display device of the
wearable device and sends one or more notifications, e.g.,
mini-goal notification information, etc., to the display device of
the wearable device providing information on a progress of the user
for reaching the mini goal. For example, the non-sedentary goal
manager 340 sends an indication of the progress to notify the user,
via a vibration of the wearable electronic device, and/or a message
displayed on the display device of the wearable electronic device,
and/or a sound emitted by the speaker of the wearable electronic
device, of remaining activity to perform to achieve the mini goal
before an end of the predetermined window of time. A non-exhaustive
exemplary list of notifications and messages that the user receives
as part of the mini goal includes "xx MORE STEPS"; "xx STEPS TO
GO!"; "xx STEPS LEFT"; "TAKE xx STEPS BEFORE 3 PM"; "xx STEPS TO
HOURLY GOAL"; "10 MIN TO GET xx STEPS!"; "xx/yy STEPS DOWN, xx TO
GO!"; "every step counts! xx MORE this hour!"; "Only xx steps to go
till yy"; and "take xx (animated feet/steps)", where xx is replaced
by a number of steps left, and yy is replaced with a total number
of steps set to be achieved for the mini-goal.
[0085] In some embodiments, instead of receiving an indication of
how many steps remain or a length of an activity that remains to
achieve the mini goal, the user receives a notification, e.g., a
message, mini-goal notification information, etc., via a vibration
of the wearable electronic device, and/or a message displayed on
the display device of the wearable electronic device, and/or a
sound emitted by the speaker of the wearable electronic device,
asking him/her to start being active, e.g., walk, run, etc., and
later receives a "celebration message" via a vibration of the
wearable electronic device, and/or a message displayed on the
display device of the wearable electronic device, and/or a sound
emitted by the speaker of the wearable electronic device, for
achieving the mini goal. For example, the non-sedentary goal
manager 340 determines that the mini goal is achieved and provides
a notification of achieving the mini goal to the user via a
vibration of the wearable electronic device, and/or a message
displayed on the display device of the wearable electronic device,
and/or a sound emitted by the speaker of the wearable electronic
device. The mini goal is sometimes referred to herein as a mini
celebration. For example, the mini celebration is "a buzz+smiley",
when the user hits yy steps during the predetermined window of time
set for the mini goal, e.g., during 1 hour, etc. The buzz is an
example of a vibration of the wearable electronic device. In some
embodiments, the wearable electronic device includes a tactile
feedback device that vibrates to provide a tactile feedback to the
user to provide a notification to the user.
[0086] While in some embodiments, the predetermined window of time
for which the mini goal, e.g., a non-sedentary goal, etc., is to be
achieved is 1 hour, in various embodiments a different
predetermined time window, e.g., in a range of 10 minutes to 6
hours, or a range of 20 minutes to 3 hours, every 2 hours, etc., is
used. In several embodiments, the predetermined window of time for
which the mini goal, e.g., a non-sedentary goal, etc., is to be
achieved is configurable, e.g., the user selects a length of the
predetermined window of time for achieving the mini goal by setting
preferences, in a manner described above. In some embodiments, the
predetermined window of time for which the mini goal is to be
achieved is dynamically adjusted, e.g., reduced or increased based
on various factors, etc., by the sedentary state monitor 124. In
some embodiments, the predetermined window of time for which the
mini goal is to be achieved is capable of being automatically
disabled by the sedentary state monitor 124 and/or manually
disabled by the user.
[0087] In various embodiments, the user further determines
preferences regarding timing for receiving notifications and
reminders regarding his/her progress towards the mini goal and
provides the preferences via the input device of the wearable
electronic device or via the input device of one of the other
electronic devices to the sedentary state monitor 124. For example,
the user desires to receive a notification some minutes prior to
the end of the predetermined window of time, e.g., 50 minutes into
the hour, etc., before achieving the mini goal. The notification
includes information indicating that the mini goal is to be
achieved and remaining activities, e.g., a number of non-sedentary
minutes, a number of steps, etc., to perform to achieve the mini
goal. If the user completes the mini goal before the predetermined
window of time ends, the user receives a rewarding message from the
sedentary state monitor 124 and receives a prize from the sedentary
state monitor 124 for that achievement.
[0088] A non-exhaustive exemplary list of celebration messages that
the user receives for achieving the mini goal is presented herein:
""; "great job!"; ":-D:-D:-D"; ":):):):)"; "xx/yy! ! !"; "another
moving hour!"; "winner"; "winner winner chicken dinner"; "champion!
champion!"; "xx down!"; "very good!"; "every extra step matters!";
"you=step machine"; "you=on fire!"; "you=awesome!"; "hourly step
champ"; "xx steps isn't even that much"; and "my hero", where xx is
replaced by a number of steps completed during the predetermined
window of time allocated for that mini-goal, and yy is replaced
with a number of steps set to be achieved for the mini goal.
Further in some embodiments, the user competes with friends via the
social network for most mini goals reached.
[0089] In various embodiments, the non-sedentary goal manager 340
tracks and records mini goals set and achieved by the user and
presents the mini goals set and/or achieved to the user. The mini
goals are presented to the user on the display device of the
wearable electronic device or one of the other electronic devices,
which receives the mini goals from the wearable electronic device
via the communication device of the wearable electronic device and
the communication device of the one of the other electronic
devices. The user then views his/her sedentary behavior and tracks
his/her improvement in achieving the mini-goal over time.
[0090] In several embodiments, the sedentary alert manager 330
differs from the non-sedentary goal manager 340 in that the
sedentary alert manager 330 works on a current sedentary period of
time that started when the state of the user transitioned to
sedentary, while the non-sedentary goal manager 340 operates off
set time windows irrespective of whether the state is sedentary at
a beginning of each time window. As previously discussed, two or
more of the managers are used in combination to interact with the
user via the sedentary state monitor 124 and the wearable
electronic device to alter his/her sedentary behavior.
[0091] Embodiments describing learning alerts follow.
[0092] In some embodiments, a sedentary learning unit 350 of the
sedentary state monitor 124 (FIG. 3), is coupled to the managers
320, 330, and 340, and receives notification information, e.g., one
or more notifications, etc., sent to the user via the sedentary
state monitor 124 (FIG. 1A) from each one of the managers 320, 330,
and 340, and determines which of the one or more notifications had
an effect of modifying a sedentary behavior of the user. For
example, the sedentary learning unit 350 determines which of the
one or more notifications succeeded in altering general sedentary
behavior of the user by limiting a length of the sedentary period
of time.
[0093] While in some embodiments, each of the managers 320, 330,
and 340 transmits the notification information regarding a time at
which the one or more notifications, e.g., the non-sedentary state
transition notification information, the sedentary alert
notification information, and the mini-goal notification
information, etc., is sent, in various embodiments, the managers
320, 330, and 340 transmit more, less, or different data as part of
the notification information. For example, the managers 320, 330,
and 340 transmit a type of notification, e.g., a message, a
vibration, and/or a sound, to the sedentary learning unit 350. As
another example, the managers 320, 330, and 340 transmit
information regarding a result of a notification sent to the user,
e.g., whether the user ended his/her sedentary period, etc. to the
sedentary learning unit 350.
[0094] In some embodiments, the sedentary learning unit 350
receives the sensor data 150 (FIG. 1A) from the one or more sensors
110 (FIG. 1A) to determine whether a transmitted notification had
an effect of modifying a sedentary behavior of the user. The
sedentary learning unit 350 records the sensor data 150 over a
period of time to learn which type of notification, e.g.,
personality or tone of a message, etc., and which context, e.g., a
time, a location, etc., has a desired effect on the user. Examples
of the desired effect include a decrease in long periods of
sedentary time, a decrease in a number of the sedentary states over
time, a decrease in a number of sedentary statuses over time, etc.
The sedentary learning unit 350 determines improved preferences and
settings, e.g., configuration parameters, etc., for configuring at
least one of the managers 320, 330, and 340 based on the
notification information received.
[0095] The sedentary learning unit 350 learns a behavior of the
user in response to the notifications from the managers 320, 330,
and 340 and reacts to the user's behavior to improve the user's
response to the notifications. For example, the sedentary learning
unit 350 changes a configuration of one of the managers 320, 330,
and 340, e.g., by transmitting configuration parameters to that
manager, etc., to change to a time of day when the user might
respond to a notification when the sedentary learning unit 350
determines that at another particular time of a day, the user never
responds to the notification. As another example, the sedentary
learning unit 350 changes a configuration of the sedentary alert
manager 330 by modifying a length of the threshold sedentary period
after which a notification is sent to the user. As yet another
example, the sedentary learning unit 350 modifies a type of
notification sent to the user, e.g., configures one of the managers
320, 330, or 340 to send a message to be displayed on the display
device of the wearable electronic device instead of a vibration
alert, e.g., a buzz, etc., or to cause an emission of a sound by
the speakers of the wearable electronic device instead of a
vibration, or to change the sound emitted, or to change the tone of
a message, or to modify the type of notification.
[0096] In some embodiments, the sedentary learning unit 350 changes
a plurality of configuration parameters such that one of the
managers 320, 330, and 340 operates at a given time of the day. For
example, the sedentary learning unit 350 determines that between
certain hours of the day, e.g., 8 AM to 12 PM, etc., the user's
response to notifications received from the non-sedentary state
transition manager 320 is better than the user's response to
notifications received from the sedentary alert manager 330. In
this example, the sedentary learning unit 350 determines
configuration parameters that disable a use of the sedentary alert
manager 330 during those hours, e.g., 8 AM to 12 PM, etc. While the
sedentary alert manager 330 and the non-sedentary state transition
manager 320 are described in this example, in various embodiments,
the sedentary learning unit 350 determines configuration parameters
to disable or enable another manager, e.g., the non-sedentary goal
manager 340, etc., and/or determines other hours of day during
which to configure the managers 320, 330, or 340. While in several
embodiments, the sedentary learning unit 350 changes a
configuration of at least one of the managers 320, 330, and 340, in
some embodiments, the sedentary learning unit 350 transmits a
recommendation of a configuration of at least one of the managers
320, 330, and 340 to the display device of the wearable electronic
device to be approved by the user prior to the configuration of the
at least one of the managers 320, 330, and 340 with the changed
configuration parameters.
[0097] In various embodiments, the sedentary learning unit 350
allows the user to snooze the sedentary alert notification
information, such that the wearable electronic device reminds the
user at a later time to perform a non-sedentary activity. The
sedentary learning unit 350 records data related to an act,
performed by the user via the input device of the wearable
electronic device or the input device of one of the other
electronic devices, of snoozing the sedentary alert notification
information. For example, the data related to the act of snoozing
includes a type of notification snoozed, a time at which the
notification is snoozed, the state, e.g., sedentary, non-sedentary,
etc., of the user at that time, a geographical location at which
the notification is snoozed, etc. The sedentary learning unit 350
uses the data related to the act to change a configuration of one
or more of the managers 320, 330, and 340. For example, if the user
snoozes one or more of the managers 320, 330, and 340 at a
particular time of a day, a configuration is changed in the manager
to avoid operating during that time. This is used to improve the
user's experience and instill greater confidence in the wearable
electronic device. In some embodiments, the sedentary learning unit
350 is implemented using one or more of the following: a decision
tree, a random forest, a support vector machine, a neural network,
a K-nearest neighbor, a Naive Bayes, and Hidden Markov Models.
[0098] In various embodiments, the user is able to set preferences
for a type of notification received based on his/her sedentary
behavior. For example, the user is able to select a subset of
subunits, e.g., the non-sedentary state transition manager 320, the
sedentary alert manager 330, the non-sedentary goal manager 340,
etc., of the sedentary state monitor 124 via the input device of
the wearable electronic device or the input device of one of the
other electronic devices for use in notifying the user based on
his/her sedentary behavior. Furthermore, the user is able to select
a sound, a particular message to be displayed on the display device
of the wearable electronic device, and a vibration for each type of
message received on the wearable electronic device. The user
chooses a combination of the types of notifications to be received
simultaneously. The user sets the sedentary state monitor 124 via
the input device of the wearable electronic device or the input
device of one of the other electronic devices such that the
sedentary periods are monitored within specific intervals of times.
For example, the user desires to monitor the sedentary periods or
the non-sedentary periods during a day between 8 AM and 8 PM.
[0099] Embodiments describing a classification of the status of the
user based on the MET measures follow.
[0100] In some embodiments, the MET measures are used to determine
the sedentary status or the non-sedentary status of the user. Thus,
the MET measures are sometimes referred to as sedentary
coefficients. The user status classifier 120 (FIG. 1A) receives a
MET measure for a moment of interest and determines whether the MET
measure is below a predetermined threshold. When the MET measure is
below the predetermined threshold, the status of the user for that
moment of interest is classified as being the sedentary status by
the user status classifier 120. When the MET measure is above the
predetermined threshold, the status of the user is classified as
being non-sedentary for that moment of interest by the user status
classifier 120 and the user is determined to be active by the user
status classifier 120.
[0101] FIG. 6A illustrates a recordation of the MET measures at
consecutive moments of interest over a period of time and a
classification of a status 612 of the user by the user status
classifier 120 (FIG. 1A) at each moment of interest based on the
MET measures, in accordance some embodiments described in the
present disclosure. The status 612 of the user is classified 614 as
being non-sedentary by the user status classifier 120 at a moment
of interest based on a MET measure exceeding a threshold MET value
at that moment of interest, according to several embodiments
described in the present disclosure. The MET measures are generated
by the sensor data analyzer 112 (FIG. 1A) for a number of moments
of interest, e.g., F.sub.1, F.sub.2 . . . F.sub.N, etc., and each
MET measure, e.g., MET value, etc., is compared by the user status
classifier 120 with the threshold MET value used for determination
630 of the sedentary status. MET measures 624 are all below the
threshold MET value as determined by the user status classifier
120, and each moment of interest for the MET measures 624 is
classified 614 and recorded as having the sedentary status by the
user status classifier 120 within a memory device, e.g., the
computer-readable media, etc., of the wearable electronic device or
of one of the other electronic devices. Comparatively, MET measures
626 all exceed the threshold MET value as determined by the user
status classifier 120, and each moment of interest for the MET
measures 626 is recorded by the user status classifier 120 within
the memory device as having the non-sedentary status. MET measures
628 are associated with sedentary and non-sedentary moments of
interest by the user status classifier 120. For example, two of the
MET measures 628 are above the threshold MET value as determined by
the user status classifier 120, and each moment of interest 628B
for the two of the MET measures 628 is identified as having the
non-sedentary status by the user status classifier 120. The two
other illustrated MET values of the MET measures 628 are below the
threshold MET value as determined by the user status classifier
120. Each moment of interest 628A and 628C for the two other MET
values is identified as having the sedentary status by the user
status classifier 120. In some embodiments, the threshold MET value
is within the range of 0.8-1.8 MET, e.g., 1.5 MET, etc. The
classification 614 of the moments of interest illustrated at FIG.
6A yields sedentary and non-sedentary moments of interests
illustrated in FIG. 2.
[0102] FIG. 6B illustrates a recordation of the MET measures at
consecutive moments of interest over a period of time and a
classification of the status of the user by the user status
classifier 120 (FIG. 1A) at each moment of interest based on the
MET measures, in accordance with various embodiments described in
the present disclosure. The status of the user is classified as
being non-sedentary at a moment of interest based on a MET measure
exceeding a first threshold MET value at that moment of interest.
The status of the user is classified as being sedentary at a moment
of interest based on a MET measure being below a second threshold
MET value at that moment of interest. In addition, the status of
the user is classified as being sedentary at a moment of interest
if the MET value exceeds the second threshold MET value, is below
the first threshold MET value, and it is further preceded and
followed by a moment of interest with a sedentary status. In some
embodiments, a group of N consecutive moments are classified as
having sedentary status if a MET measure associated with each
moment is between the first and the second threshold MET values and
the group of N consecutive moments of interest is immediately
preceded and succeeded by a moment of interest with a sedentary
status. Examples of N consecutive moments of interest include
moments of interest, each occurring at 1 minute time intervals
(e.g., where N is between 1 and 5), or each occurring at time
intervals between 1 minute and 5 minutes, or each having 1 second
time intervals (e.g., where N is between 1 and 300), or each
occurring at time intervals between 1 second and 300 seconds, etc.
If the N moments of interest occur at longer time intervals, e.g.,
every 10 minutes, etc., then N is smaller, e.g., 2, etc. In the
embodiments discussed above, the second threshold MET value is
lower than the first threshold MET value.
[0103] Each of the MET measures generated by the sensor data
analyzer 112 is compared by the user status classifier 120 with the
first threshold MET value used for recording a non-sedentary status
632 and with the second threshold MET value used for recording a
sedentary status 634. The recordation of the non-sedentary status
632 and the sedentary status 634 in the memory device is performed
by the user status classifier 120. MET measures 646 are all above
the first threshold MET value, and each moment of interest for the
MET measures 646 as determined by the user status classifier 120 to
have the non-sedentary status is recorded by the user status
classifier 120. The MET measures 644 are all below the second
threshold MET value as determined by the user status classifier
120, and each moment of interest for the MET measures 644 is
recorded by the user status classifier 120 as having the sedentary
status. Comparatively, some of MET measures 648 exceed the second
threshold MET value but are below the first threshold MET value as
determined by the user status classifier 120, while other ones of
the MET measures 648 are below the second threshold MET value as
determined by the user status classifier 120. A first moment of
interest of a group of contiguous moments of interest for the MET
measures 648 has a MET value below the second MET threshold value
as determined by the user status classifier 120, while a second
moment of interest and a third moment of interest for the MET
measures 648 has a MET value between the first and the second
threshold MET values as determined by the user status classifier
120, immediately followed by moments of interest with a MET value
below the second threshold MET value. In this example, all moments
of interest for the MET measures 648 are determined by the user
status classifier 120 as having the sedentary status despite having
two moments within the contiguous group of moments with MET
measures exceeding the second threshold MET value.
[0104] As described above, in some embodiments, a MET measure
determines the non-sedentary status of the user associated with a
particular type of activity of the user. For example, according to
a MET measure, the user status classifier 120 determines whether
the user is running, walking, sprinting, bicycling, swimming or
performing another type of non-sedentary activity. To further
illustrate, if a MET measure is within a range of 2.5 to 3.2, a
status of the user is classified as "non-sedentary, bicycling". As
another example, if a MET measure is within a range of 3.2 to 3.8,
a status of the user is classified as "non-sedentary, walking". As
yet another example, is a MET measure is between 6.7 to 7.3, e.g.,
e.g., 7.0, etc., a status of the user is classified as
"non-sedentary, jogging".
[0105] Embodiments describing a classification based on other
sensor information follow.
[0106] In some embodiments, the sedentary status of the user for a
moment of interest is determined by the user status classifier 120
based on the sensor data 150 (FIG. 1A), e.g., the motion sensor
data and/or the biometric data, etc., received from the one or more
sensors 110 (FIG. 1A) without the generation of the MET measures.
For example, the sedentary status of the user is determined based
on the motion measures, e.g., also sometimes referred to as
movement measures, etc., and/or the heart rate measures without
calculation of MET measures. Some embodiments of a classification
of a status of the user at a moment of interest are described in
U.S. Pat. No. 8,548,770 "Portable monitoring devices and methods of
operating same," which is incorporated by reference herein in its
entirety.
[0107] Description of exemplary devices with automatic detection of
the user's sedentary state or the non-sedentary state and providing
notification to the user based on the sedentary state follow.
[0108] As previously described, while in some embodiments, one or
more of the operations, described above, are implemented in the
wearable electronic device, in various embodiments, one or more the
operations are distributed among electronic devices, e.g., the
wearable electronic device and the other electronic devices, etc.
FIG. 7 illustrates examples of one such distribution. FIG. 7 is a
block diagram illustrating a wearable electronic device 702 and an
electronic device 700 implementing operations disclosed according
to various embodiments described in the present disclosure. The
electronic device 700 is an example of one of the other electronic
devices. The wearable electronic device 702 includes a processor
742 and the one or more sensors 110. In some embodiments, instead
of the processor 742, multiple processors are used in the wearable
electronic device 702.
[0109] In some embodiments, the one or more sensors 110 include the
motion sensor 727, examples of which include a multi-axis
accelerometer, a gyroscope, a gravity sensor, a rotation vector
sensor, and a magnetometer. Moreover, in various embodiments, the
one or more sensors 110 include one of more other sensors 714,
which include a photoplethysmographic sensor 720. In several
embodiments, the one or more other sensors 714 include a
temperature sensor 721, an ambient light sensor 722, a galvanic
skin response sensor 723, a capacitive sensor 724, a humidity
sensor 725, and a sound sensor 726.
[0110] The wearable electronic device 702 also includes a
non-transitory machine readable storage medium 718, which contains
the sensor data analyzer 112 as discussed herein above. When
executed by the processor 742, the sensor data analyzer 112 causes
the wearable electronic device 702 to generate the analyzed sensor
information 152 for moments of interest. The wearable electronic
device 702 performs functionalities relating to the user status
classifier 120, the time period detector 122, and/or the sedentary
state monitor 124, some or all of which are included in a sedentary
tracking and notification module (STNM) 750, which is stored in the
non-transitory machine readable storage medium 718. When executed
by processor 742, the STNM 750 causes the wearable electronic
device 702 to perform corresponding operations discussed herein
above. The wearable electronic device 702 further includes the user
interface 126 having a display device 732. Examples of a display
device includes a liquid crystal display (LCD) display device, a
light emitting diode (LED) display device, a plasma display device,
etc. In some embodiments, the user interface 126 includes a
speaker, a haptic screen, and/or a vibration mechanism, e.g., a
haptic communication device, a rumble pack, a kinesthetic
communication device, etc., to allow communication and interaction
with the user wearing the wearable electronic device 702.
[0111] In some embodiments, the one or more other sensors 714 are
not placed within the wearable electronic device 702. The one or
more other sensors 714 are distributed around the user. For
example, the one or more other sensors 714 are placed on a chest of
the user, or a mattress on which the user lies, or a bedside table
located by the user, while the wearable electronic device 702 is
worn by the user.
[0112] FIG. 7 also includes an embodiment of the electronic device
700, e.g., the server including hardware and software, a tablet, a
smartphone, etc., containing an application. In some embodiments,
the electronic device 700 performs functionalities relating to the
user status classifier 120, the time period detector 122, and/or
the sedentary state monitor 124, some or all of which are included
in the STNM 750, which is stored in a non-transitory machine
readable storage medium 748 of the electronic device 700. For
example, the STNM 750, instead of being stored in the
non-transitory machine readable storage medium 718 of the wearable
electronic device 702, is stored in the non-transitory machine
readable storage medium 748 of the electronic device 700 for
execution by a processor 752 of the electronic device 700. In some
embodiments, the sensor data analyzer 112 is stored in the
non-transitory machine readable storage medium 748 instead of being
stored in the non-transitory machine readable storage medium 718,
and is executed by the processor 752.
[0113] When executed by processor 752, the STNM 750 causes the
electronic device 700 to perform corresponding operations discussed
herein above. In some embodiments, the electronic device 700
contains virtual machines (VMs) 762A to 762R, each of which
executes a software instance 766 or a software instance 768 of the
STNM 950. A hypervisor 754 presents a virtual operating platform
for the virtual machines 762A to 762R.
[0114] The wearable electronic device 702 collects one or more
types of the sensor data 150, e.g., biometric data, etc., from the
one or more sensors 110 and/or external devices, and then utilizes
the sensor data 150 in a variety of ways. Examples of the biometric
data include data pertaining to physical characteristics of a human
body, such as, for example, a heartbeat, a heart rate, perspiration
levels, etc. Other examples of the sensor data 150 include data
relating to a physical interaction of the human body with an
environment, such as accelerometer readings, gyroscope readings,
etc. An example of the external devices includes an external heart
rate sensor or monitor, e.g., a chest-strap heart rate sensor or
monitor, etc. Examples of utilizing the sensor data 150 in the
variety of ways include making calculations based on the sensor
data 150, storing the sensor data 150, storing the calculations in
the non-transitory machine readable storage media 718,
automatically acting on the sensor data 150, automatically acting
on the calculations, communicating the sensor data 150 to a
communication device, such as, one or more network interface
controllers 744, etc., of the electronic device 700 over the
computer network, such as, for example, the Internet, a wide-area
network, a local area network, etc., and communicating the
calculations to the communication device over the computer network.
Examples of automatically acting on the calculations include an
automatic watch check and dismissal gesture detection. As described
herein, the wearable electronic device 702 also receives data,
e.g., notifications, etc. from one of the other electronic devices
for storage and/or display on the display device 732.
[0115] In some embodiments, the electronic device 700 includes a
display device for presenting any notifications described herein,
e.g., the non-sedentary state transition notification information,
the sedentary alert notification information, and the mini-goal
notification information, etc., which are received from the
wearable electronic device 702. For example, the sedentary state
monitor 124 of the wearable electronic device 702 generates a
notification and sends the notification via a communication device
of the wearable electronic device 702 and a communication device of
the electronic device 700 to the display device of the electronic
device 700 for display on the display device 700.
[0116] In various embodiments, the sensor data 150 is obtained by
the wearable electronic device 702 and send via the communication
device of the wearable electronic device 702 and the communication
device of the electronic device 700 to the STNM 750 of the
electronic device 700 for performing the operations described
herein.
[0117] In several embodiments, a notification is generated by the
electronic device 700 and is sent from the one or more network
interface controllers 744 to the communication device of the
wearable electronic device 702 via the computer network for display
of the notification on the display device 732. In various
embodiments, the sedentary state monitor 124 of the electronic
device 700 generates a notification and sends the notification via
a communication device of the electronic device 700 and a
communication device of the wearable electronic device 702 to the
display device 732 for display on the display device 732.
[0118] FIG. 8 is a block diagram of an embodiment of a
wrist-mounted electronic device having a button, a display, and a
wrist band to secure the wrist-mounted electronic device to a
user's forearm, according to several embodiments described in the
present disclosure. For example, FIG. 8 depicts the wearable
electronic device 702, such as illustrated in FIG. 7, and that is
worn on the user's forearm, like a wristwatch. In FIG. 8, the
wrist-mounted electronic device has a housing 802 that contains
electronics, e.g., components illustrated in FIG. 7, etc.,
associated with the wrist-mounted electronic device, a button 804,
and a display screen 806 accessible or visible through the housing
802. The display screen 806 is of the display device 732 (FIG. 7).
A wristband 808 is integrated with the housing 802.
[0119] In some embodiments, the wrist-mounted electronic device
incorporates one or more user interfaces including, but not limited
to, visual, auditory, touch/vibration, or combinations thereof. In
some embodiments, the wrist-mounted electronic device provides
haptic feedback through, for instance, a vibration of a motor. In
some implementations, the one or more sensors 110 (FIG. 1A) are
used as part of the one or more user interfaces, e.g.,
accelerometer sensors are used to detect when the user taps the
housing 802 of the wrist-mounted electronic device with a finger or
other object and then interprets such data as a user input for
purposes of controlling the wrist-mounted electronic device. For
example, double-tapping of the housing 802 of the wrist-mounted
electronic device is recognized by the wrist-mounted electronic
device as a user input.
[0120] While FIG. 8 illustrates an implementation of the
wrist-mounted electronic device, in some embodiments, the
wrist-mounted electronic device has other shapes and sizes adapted
for coupling to, e.g., secured to, worn, borne by, etc., a body or
clothing of the user. For example, the wrist-mounted electronic
device is designed such that it is inserted into, and removed from,
a plurality of compatible cases or housings or holders, e.g., a
wristband that is worn on the user's forearm or a belt clip case
that is attached to the user's clothing. As used herein, the term
"wristband" refers to a band that is designed to fully or partially
encircle the user's forearm near a wrist joint. The band is
continuous, e.g., without any breaks, or is discontinuous, or is
simply open. An example of the continuous band includes a band that
stretches to fit over the user's hand or has an expanding portion
similar to a dress watchband. An example of the discontinuous band
includes a band having a clasp or other connection allowing the
band to be closed, similar to a watchband. An example of the open
band is one having a C-shape that clasps the user's wrist.
[0121] It should be noted that in some embodiments, information,
e.g., notifications, etc., are accessed by the user after logging
into a user account. For example, the user provides his/her user
information, e.g., user name, password, etc., and when the user
information is authenticated by the server, the user logs into the
user account. In these embodiments, the notifications are posted
within the user account. The user account is stored on the
server.
[0122] In some embodiments, the user accesses the user account to
view graphs illustrated in FIGS. 2, 4, 5, 6A, and 6B. The graphs
are viewed on the display device of the wearable electronic device
or on the display device on one of the other electronic
devices.
[0123] Some embodiments of the wearable electronic device and of
one of the other electronic devices are described in application
Ser. No. 15/048,965, filed on Feb. 19, 2016 and titled "Generation
of Sedentary Time Information by Activity Tracking Device", in
application Ser. No. 15/048,972, filed on Feb. 19, 2016 and titled
"Temporary Suspension of Inactivity Alerts in Activity Tracking
Device", in application Ser. No. 15/048,976, filed on Feb. 19, 2016
and titled "Live Presentation of Detailed Activity Captured by
Activity Tracking Device", and in application Ser. No. 15/048,980,
filed on Feb. 19, 2016 and titled "Periodic Inactivity Alerts and
Achievement Messages", all of which are incorporated by reference
herein in their entirety.
[0124] It should be noted that in an embodiment, one or more
features from any embodiment described herein are combined with one
or more features of any other embodiment described herein without
departing from a scope of various embodiments described in the
present disclosure.
[0125] While the invention has been described in terms of several
embodiments, those skilled in the art will recognize that the
invention is not limited to the embodiments described, can be
practiced with modification and alteration within the spirit and
scope of the appended claims. The description is thus to be
regarded as illustrative instead of limiting.
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